BR112015008601B1 - MORTAR - Google Patents

Abstract

mortar a mortar contains cement, one or more of a mineral additive, superplasticizer, aggregates, hydroxyethyl methyl cellulose and water, methyl in which hydroxyethyl methyl cellulose is characterized by the sum of its molecular substitution with hydroxyethyl and the degree of methyl substitution is 1, 90 and above and 2.30 or below and its viscosity as a 2 weight percent aqueous solution that is below 30,000 millipascals * second.

Description

BACKGROUND OF THE INVENTION Field of invention

[01] The present invention relates to mortars suitable for use in self-compacting concrete formulations and, in particular, such mortars comprising hydroxyethyl methyl cellulose.

Introduction

[02] Specialized concrete known as self-compacting concrete (SCC), also known as self-consolidating concrete, is a relatively new specialized material. Development of SCC has been attributed to Japanese researchers who have discovered a concrete formulation now known as SCC. SCC compositions are different from other concrete formulations. SCC can flow around obstructions in a mold and flow into the corners of a mold exclusively under its own weight without the need for vibration to distribute the concrete in the mold. SCCs tend to flow without trapping air, thus allowing leakage of durable concrete structures of complex shapes without the complication of vibration of the structure during casting to distribute material and remove air.

[03] To obtain the desired performance of a SCC, the formulation must have a low yield stress and a high plastic viscosity. Runoff voltage is a measure of the amount of energy needed to make the SCC flow. To qualify as an SCC, concrete must flow under its own weight. For a concrete to flow under its own weight it must have a low yield stress. Plastic viscosity is a measure of the strength a material has to flow, as a result of internal friction. SCC must have a high plastic viscosity in order to maintain a homogeneous mixture of suspended aggregates instead of allowing the aggregates to segregate within the concrete formulation. The SCC must have a high plastic viscosity, avoiding segregation, excessive leakage and excessive air trapping. In order to achieve these desirable properties, SCC has a unique composition and is sensitive to changes in composition.

[04] The yield stress, plastic viscosity and other rheological properties of an SCC are dictated by the SCC mortar (that is, the properties of an SCC mortar). It is common to develop concrete formulations by first developing mortar compositions with desirable rheological properties. The mortar can then be formulated with appropriate aggregate to form an SCC. Useful methods for characterizing a mortar to determine if it is suitable as an SCC mortar include a settlement test, V-hopper discharge time and leak value. To be suitable for use as an SCC formulation, it is particularly desirable for a mortar to simultaneously have a seating value that is greater than 290 millimeters, a V funnel discharge time that is less than five seconds and a pour value that is less than three percent.

[05] One of the components frequently used in SCC and SCC mortar is a viscosity modifying agent (VMA). VMAs usually serve to increase the viscosity of a mortar and concrete. VMAs help prevent segregation and leakage and provide a concrete formulation that is robust against water variation and variation of raw materials. However, selecting a suitable VMA is a challenge, because while VMA desirably increases viscosity, it can also undesirably increase the SCC yield stress and thus inhibit its self-compacting nature or increase its likelihood of intercepting air bubbles. Therefore, the selection of a suitable VMA for SCCs and SCC mortars is mainly restricted to a relatively small group of materials. Examples of common VMA used in SCCs include starch (which tends to negatively influence the yield stress) clay (which tends to negatively influence the yield stress), Welan gum and diutan gum (which are expensive and which tend to impact negatively the plastic viscosity), hydroxyethyl cellulose (which tends to negatively impact the flow properties) and synthetic polymers based on polyacrylates (which are expensive and which tend to negatively impact the flow stress).

[06] It is desirable to identify an alternative VMA suitable for use in SCC and SCC mortar that offers advantages over the current VMA. For example, hydroxyethyl methyl cellulose (HEMC) is a VMA that is less expensive than many of the common VMAs. However, HEMC polymers are not used in SCC formulations because they tend to have a very high, viscosity, which results in a settlement value that is too low for an SCC quality. HEMCs also tend to induce the incorporation of air into a mortar and concrete, thus resulting in lower density and lower quality mortar and concrete. It is desirable to identify a VMA alternative that is suitable for the formulation of an SCC mortar that simultaneously has a settlement value that is greater than 290 millimeters, a V-funnel discharge time that is less than five seconds and a leak value which is less than three percent. It would also be desirable if the VMA did not result in undesirably high air retention as experienced with typical HEMCs.

BRIEF SUMMARY OF THE INVENTION

[07] The present invention offers a suitable mortar, such as SCC mortar, or even a SCC, which comprises an alternative VMA. In particular, the present invention provides an SCC mortar that comprises a special HEMC that surprisingly provides a suitable combination of properties that meets the needs of an SCC mortar. In contrast to most HEMCs, the HEMCs used in the present invention do not have an excessively high viscosity (greater than 30,000 milliPascals * seconds for a 2% by weight aqueous solution) and can produce a SCC mortar with a desirable setting (greater than 290 millimeters), a V-hopper discharge time that is five seconds or less, and a leakage value, which is less than three percent. HEMC even more surprisingly induces less air trapping than other HEMC options.

[08] Surprisingly the research that led to the present invention revealed that HEMCs with a viscosity in an aqueous solution at 2 percent by weight that is below 30,000 milliPascals * seconds and characterized by the sum of the hydroxyethyl (MS) molecular substitution and degree of substitution of methyl (DS) being 1.90 or higher and 2.30 or less can serve as viscosity modifying agents as suitable in the preparation of mortars acceptable as SCC mortars (that is, mortars with the above desirably mentioned settlement values, V funnel discharge and leak values), even when other HEMCs are not suitable, in such a use. More surprisingly, the particular HEMC, further characterized by a value greater than MS 0.01 and 0.5 or less in combination with a DS value greater than 1.65 and 2.2 or less, is particularly beneficial in obtaining values of desirable settlements, V-hopper discharge time and leakage values while achieving less air trapping than other HEMCs.

[09] In a first aspect, the present invention is a mortar comprising cement, one or more of a mineral additive, superplasticizer, aggregates, a hydroxyethyl methyl cellulose and water, in which the hydroxyethyl methyl cellulose is characterized by the sum of its substitution molecular hydroxyethyl and methyl substitution degree is 1.90 or higher and 2.30 or lower and its viscosity as a 2 weight percent aqueous solution that is below 30,000 milliPascals * seconds.

[10] The present invention is particularly useful as a self-compacting concrete for use anywhere where self-compacting concrete is used today.

DETAILED DESCRIPTION OF THE INVENTION

[11] Test methods refer to the most recent test method as of the priority date of this document, unless the test method number includes a different date. Test method references contain both a reference to the test company and the test method number. The following abbreviations for the test method apply here: ASTM refers to ASTM International (formerly known as the American Society for Testing and Materials); EN refers to the European Standard; NF refers to the French Association for Standardization; DIN refers to the Deutsches für Normung Institute; and ISO refers to the International Organization for Standards.

[12] "Multiple" means two or more. "And / or" means "and, or as an alternative". All ranges include extreme points unless otherwise noted. "Comp Ex" and "Comparative Example" are interchangeable as are "Example" and "Ex".

[13] "Mortar" here refers to a formulation that comprises cement, water, and optionally additional additives. Mortars typically still comprise mineral additives, aggregates and a viscosity modifier.

[14] "Concrete" here refers to a mortar that comprises coarse aggregates.

[15] Mortars of the present invention comprise cement, water, fines, superplasticizer, aggregates and hydroxyethyl methyl cellulose and are particularly desirable for use in self-compacting concrete formulations.

[16] Cement can be any cement suitable for use in self-compacting concrete (SCC) formulations. For example, cement may be one or any combination of more than one cement selected from hydraulic calcium silicate cement, lime containing cement, alkaline cement, plaster and plaster. Particularly desirable is Portland cement, especially types EMC I, II, III, IV, and V and / or alumina cement (aluminate cement).

[17] Mineral additives are selected from slag (as defined in NF EN 197-1 Standard, point 5.2.2), pozzolanic materials (as defined in NF EN197-1 Standard, point 5.2.3), gray as (as defined in NF EN 197-1 Standard, point 5.2.4), fly ash (as defined in NF EN 197-1 paragraph Standard 5.2.4), shale (as defined in NF EN 197-1 paragraph Standard 5.2.5), limestone (as defined in NF EN 197-1 paragraph Standard 5.2.6), and / or smoked silica (as defined in NF EN 197-1 paragraph Standard 5.2.7).

[18] Superplasticizer is a characteristic component of the SCC mortar that increases the fluidity of the mortar, which allows the SCC mortar (or the SCC itself) to easily conform around obstacles and fill empty spaces in a space. Superplasticizers are also known as water reducers, as they can reduce the water-cement ratio of a mortar. Superplasticizers suitable for use in the mortar of the present invention include any of those that are suitable for use in the SCC formulation. Examples of superplasticizers suitable for use in the mortar of the present invention include sulphonated melamine-formaldehyde condensates, sulphonated condensates of naphthalene formaldehyde, polycarboxylates and lignosulfonates. Superplasticizers are typically present at a concentration of 0.1% by weight or more and 2.0% by weight or less based on the total weight of cement.

[19] Aggregates are usually classified as coarse and fine aggregates. The mortar of the present invention can contain only fine aggregates, only coarse aggregates or, preferably, a combination of fine and coarse aggregates. Aggregates are classified as fine or coarse according to the ASTM C33 classification. In general, fine aggregates pass entirely through a 9.5 millimeter (mm) sieve and up to 10 percent in roasting will pass through a 150 micrometer sieve (No. 100 sieve). Coarse aggregates are classified into a number of different types according to the ASTM C33 standard and are of a larger total size distribution than fine aggregates. Aggregates are generally naturally occurring inorganic materials, such as rocks and / or minerals, where rocks are generally made up of various minerals. Fine aggregates are usually in a sand form. Coarse aggregates are often chosen from gravel, gravel and similar materials.

[20] The mortar of the present invention further comprises a particular type of hydroxyethyl methyl cellulose (HEMC). Surprisingly, the present invention is a result of the discovery of a particular type of HEMC that is suitable for use in mortars, particularly SCC mortars. The HEMC compounds of the present invention provide exclusively both the ideal flow point and levels of plastic viscosity in a mortar. It has also been found that some of the HEMC compounds trap less air than other HEMC compounds, thus causing less air trapping in a mortar than other HEMC compounds. Generally, HEMC serves to increase the plastic viscosity in a mortar without increasing the pour point to an undesirably high level. The HEMC compounds of the present invention have particular levels and types of substitution that have surprisingly been found to increase the plastic viscosity in a mortar without increasing the pour point to an undesirably high level. In addition, the HEMC of the present invention provides for a mortar that has a desirable settlement (more than 290 mm), desirable V-funnel discharge (less than five seconds in the test described here), and the desirable leakage values (less than than three percent). Preferred embodiments of the present invention have even less trapped air than mortars made with other HEMCs.

[21] The HEMC of the present invention can be characterized by its MS and DS values. The MS value is a measure of the level of molecular substitution of hydroxyethyl groups per anhydroglycosis unit of the cellulose backbone in HEMC (ie, the degree of molecular substitution of hydroxyethyl). The DS value is a measure of the degree of substitution with methyl groups per unit of anhydroglycosis of the cellulose backbone (ie, degree of methyl substitution). Determine MS and DS values for a HEMC by the Zeisel method to determine alkoxy bonds in an organic compound by treatment with hydrogen iodide and red phosphorus. Examination of the resulting alkaloids and alkenes by gas chromatography allows the determination of MS and DS values.

[22] The HEMC of the present invention is characterized by the sum of the values of MS and DS as being 1.90 or higher, preferably 1.95 or higher and, at the same time, being 2.30 or lower, and that can be 2.20 or less, 2.15 or less, 2.13 or less, even 2.10 or less.

[23] It is still desirable that s HEMC have an MS that is greater than 0.01, preferably, which is 0.05 or greater, even more preferably, which is 0.1 or greater and even more preferably, which is 0.18 or higher and, while it is 0.5 or less, preferably 0.4 or less, even more preferably 0.35 or less, even more preferably 0.33 or less. At the same time, the HEMC of the present invention, desirably, has a DS that is greater than 1.65, preferably 1.70 or higher, more preferably 1.72 or higher and even more preferably 1.8 or higher and, while it is less than 2.2, preferably 2.0 or less and more preferably 1.9 or less. If the MS value is less than 0.01, then the polymer would be essentially methyl cellulose, which has a thermo-freezing temperature low enough that the rheology control would be undesirably lost at a temperature above 30 ° C. If the MS value is greater than 0.5, then HEMC tends to result in a mortar that has excessive air trapping and retention properties, which results in undesirable low-density mortars and inferior concrete. If the DS value is less than 1.65, then HEMC would have an unacceptable effect on the delay in cement fixing. If the DS value is greater than 2.2, then the HEMC is not sufficiently soluble in water for use in a mortar. When HEMC has MS and DS values in these preferred ranges, it has been found that HEMC is less likely to trap air in a mortar than when MS and DS values are outside these preferred ranges.

[24] The HEMC of the present invention has a viscosity in aqueous solution of two percent by weight (% by weight) that is less than 30,000 milliPascals * seconds (mPa * s). At the same time, it is desirable for the HEMC to have a viscosity of 1,500 mPa * s or greater, preferably 3,000 mPa * s or greater, and more preferably 5,000 mPa * s or greater. Determine the viscosity of a two percent by weight aqueous HEMC solution at 20 ° C at a fixed shear rate of 2.55 sec-1 on a Rotovisco rheometer. Determine aqueous solution% by weight by the weight of HEMC in relation to the total weight of the solution. If the HEMC has a viscosity in a two wt% aqueous solution that is greater than 30,000 mPa * s, then the resulting mortar tends to have an undesirably low settlement and / or an undesirably long V-funnel time , which means that the flow properties of the mortar have become undesirable. If the viscosity of the HEMC is less than 1,500 mPa * s, the HEMC tends to be very ineffective in modifying the viscosity of a mortar, requiring a large amount of HEMC to be added to modify the viscosity.

[25] The concentration of HEMC in the mortar of the present invention is desirably 0.01% by weight or more, preferably 0.05% by weight or more, and at the same time it is desirably 1.0% by weight or less, preferably 0.5% by weight or less based on the total weight of the cement. If the concentration of HEMC is less than 0.01% by weight, then the mortar or concrete will leak and segregate due to insufficient stability. If the HEMC concentration is more than 1.0% by weight, then the mortar formulation becomes expensive and, depending on the HEMC viscosity, the mortar viscosity can become too high.

[26] Water is also present in the mortar of the present invention. To form a quality mortar, the water-to-cement (water / cement) volume ratio must be as small as possible. It is desirable that the mortar has a water / cement ratio of less than 0.5. Higher proportions of water / cement will result in undesirably low concrete strength. The water / cement ratio must be high enough to completely hydrolyze the cement in the mortar. Typically, the water / cement ratio is 0.4 or higher. If the water / cement ratio is below 0.4, it is difficult to hydrate the cement sufficiently and insufficiently hydrated cement will result in undesirably low strength of the mortar or concrete.

[27] The mortar can optionally comprise one or any combination of more than one additional additive, if desired. For example, one or any combination of more than one of the following additives may be present in the mortar: accelerators, retarders, dispersants, synthetic thickeners, pigments, reducing agents, and defoamers. Generally, the mortar comprises up to five% by weight of one or a combination of more than one additional additive.

[28] Mortar has the following characteristics, when characterized by an absence of coarse aggregate: settlement value of more than 290 mm, a V-funnel discharge time that is less than five seconds and a leakage value, which is less than three percent.

[29] Settlement is a measure of how much a mortar is able to flow under its own weight and thus provides an indication of the mortar's yield stress. Settlement measurement, also called settlement flow, by depositing a certain volume of mortar on wet glass and measuring the extent to which the mortar spreads. Define a cone funnel (nesting cone) having a lower opening diameter of 100 mm, a top opening diameter of 70 mm and a height of 60 mm, with the bottom opening on a moistened glass plate (wet 10 seconds before testing). Fill the cone with mortar and then quickly pull the cone vertically out from the board to fully release the mortar on the board. Once the mortar stops spreading measure the diameter of the resulting mortar cake in four locations equally spaced around the mortar cake. The average of the four diameters is the settlement value for the mortar. A laying value of more than 290 millimeters is desirable and corresponds to a mortar having a low yield strength sufficient to serve as an SCC mortar.

[30] V-hopper discharge time provides a measure of a mortar's fluidity and viscosity. The V-funnel discharge test uses a rectangular V-shaped funnel having a rectangular top opening that is 275 mm long and 30 mm wide. The opening of the funnel decreases uniformly in the dimension 275 mm to 30 mm over a height of 245 mm to form a square funnel spout of 30 mm by 30 mm that extends an additional height of 75 mm, when the funnel has a flap which can reversibly close to seal the bottom 30 mm by 30 mm of the funnel. Moisten the inner surface of the V funnel and, with the flap closed, fill it with mortar. Open the flap once the V funnel is filled and record the time it takes for the mortar to drain out of the bottom of the funnel. This time is the discharge time for the V funnel. Mortars of the present invention desirably have a discharge time for the V funnel that is less than five seconds. If the discharge time of the V funnel is more than five seconds, the mortar tends to have insufficient flow properties for an SCC.

[31] Leakage value is a measure of the degree of leakage that a mortar experiences. Leakage is the development of a layer of water on the top or surface of recently placed concrete. It is caused by the sedimentation of solid particles in the mortar accompanied by an upward displacement of the water. While some leaks are acceptable, excessive leakage increases the water-cement ratio fixes the upper surface and that can result in a weak concrete upper surface. Determine a pour value for a mortar by weighing a 500 milliliter (ml) beaker, adding approximately 375 ml of mortar to the beaker, weighing again to determine the weight of the mortar in the beaker, covering the beaker and mortar to prevent evaporation of the water and let stand for 30 minutes. After settling, remove all surface water from the top of the mortar and weigh the cup and mortar again to determine how much water has been removed. Repeat the water removal and weighing of the glass every hour until the leak stops. Calculate the leakage value as a percentage using the following formula: Leakage (%) = 100 x [total mass of water withdrawn (g)] / [(W) x (Mortar Mass)] where the Mortar Mass is mass of mortar initially placed in the cup, in grams, and W is the water mass ratio in the initial mortar, as determined by dividing the mass of water in the mortar in grams, divided by the mass of the mortar in grams. Mortars of the present invention desirably have a pour value, which is less than three percent.

[32] The mortar desirably traps as little air as possible during mixing, transport and distribution. When air is trapped in a mortar, either in the form of mortar or concrete, the resulting air voids form undesirable heterogeneities in the resulting material that can be visually unattractive and which can structurally weaken the material. One of the disadvantages of using typical HEMCs like VMA in a mortar is that HEMC tends to facilitate the retention of air in a mortar. Surprisingly, the mortar formulations of the present invention retain less air than mortar formulations containing HEMCs other than those described in the present invention. In particular, it has been found that when HEMC has an MS that is greater than 0.01, preferably, that is 0.05 or higher, even more preferably, that is 0.1 or higher and even more preferably, which is 0.18 or higher and, while it is 0.5 or less, preferably 0.4 or less, even more preferably 0.35 or less, even more preferably 0.33 or less and at the same time time, it has a DS that is greater than 1.65, preferably 1.70 or more, more preferably 1.72 or more and even more preferably 1.8 or higher and at the same time it is less than 2.2 , preferably 2.0 or less and more preferably 1.9 or less, the mortar tends to trap less air than mortars containing HEMCs outside this description.

[33] One way to compare the extent of air trapping in a mortar is by comparing the density of mortars. Similar mortars must have similar densities. A mortar with a lower density than a similar mortar has more air trapped than the mortar with a higher density. The Examples and Comparative Examples illustrate here that the mortars of the present invention tend to have a lower density than mortars comparable with HEMCs outside the scope of the present invention.

[34] Prepare mortars of the present invention by first adding all the dry components together and mixing, then adding any aqueous components, then all the remaining water and then mixing. It is desirable to take care during mixing to minimize or avoid air retention in the mortar while mixing.

[35] The following examples serve to illustrate embodiments of the present invention.

EXAMPLES Mortar Formulation

[36] Prepare the mortars for the examples and comparative examples using the components in Table 1, first preparing a dry mix 1, combining the cement, fly ash and stabilizer. Then, prepare a Dry Mix 2 by combining Aggregates 1 to 3. Then, combine the water and superplasticizer in a mixing bowl for a ToniMIX mixer (available from Toni Technik). During mixing at level 1 of mixing add Dry Mix 1 and Dry Mix 2 to the mixing bowl. Mix the resulting components for 30 seconds at level one and then for 30 seconds at level two. Leave the mixture to stand for 90 seconds to dissolve soluble additive and then homogenize again for 60 seconds at level 2. The resulting mixture serves as a mortar. Table 1

Preparation of HEMC

[37] Prepare HEMCs using a standard two-stage pressure reaction as described, for example, in EP1180526B1 and EP1589035A1. The following discussions provide more specific guidance for the HEMCs in the present examples.

HEMC for Example (Ex) 1

[38] Load of finely ground wood pulp pulp having an intrinsic viscosity of approximately 800 milliliters per gram (ml / g) for a stirred jacket reactor. Evacuate, purge the reactor with nitrogen, and then evacuate again to remove oxygen. Adjust the temperature to 25 ° C. In the first stage, spray 4.7 moles of dimethyl ether and 3.2 moles of methyl chloride on the cellulose paste per mole of cellulose. Then, quickly add 1.19 moles of sodium hydroxide (50% by weight aqueous solution) per mole of cellulose. Stir the resulting mixture for 30 minutes at 25 ° C and then add 0.5 moles of ethylene oxide per mole of cellulose to the reactor. Continuously heat the contents of the reactor to 80 ° C by raising the temperature over 30 minutes. Allow the mixture to react for 30 minutes at 80 ° C.

[39] Begin a second stage by adding another dose of 1.3 moles of methyl chloride per mole of cellulose. Then, after complete addition of methyl chloride, quickly add a new dose of 0.9 moles of sodium hydroxide (50% by weight aqueous solution) per mole of cellulose. Maintain a temperature of 80 ° C for 80 minutes to complete the reaction. Dry and grind the resulting wet HEMC by any method known in the art.

HEMC for Ex 2

[40] Prepared in the same way as HEMC for Ex 1, except for the use of 1.0 mol of sodium hydroxide per mol of cellulose in the second stage.

HEMC for Ex 3

[41] Load of finely ground wood pulp (intrinsic viscosity approx. 800 ml / g) to a stirred jacket reactor. Evacuate, purge the reactor with nitrogen, and then vacuum again to remove oxygen. Set the temperature to 45 ° C. In the first stage, spray 5.8 moles of dimethyl ether per mole of cellulose and 2.7 moles of methyl chloride per mole of cellulose on the cellulose pulp. Then, continuously add 2.3 moles of sodium hydroxide (50% by weight aqueous solution) per mole of cellulose over 18 minutes. Stir the resulting mixture for 2 minutes at 45 ° C and then add 0.48 moles of ethylene oxide per mole of cellulose to the reactor. Continuously heat the contents of the reactor to 70 ° C over a period of 45 minutes. Begin a second stage of the reaction by adding 1.9 moles of methyl chloride per mole of cellulose. Directly after adding methyl chloride evenly add 1.2 moles of sodium hydroxide (50% by weight aqueous solution) per mole of cellulose plus 31 minutes. Maintain a temperature of 70 ° C for 10 minutes. Then, heat the reactor contents in 15 minutes to 80 ° C and let it react at this temperature for 55 minutes to complete the reaction. Dry and grind the resulting moist HEMC by any method known in the art.

HEMC for Ex 4

[42] Prepared in the same way as HEMC for Ex 3, except using a wood paste with an intrinsic viscosity having approximately 1,300 ml / g and 0.32 moles of ethylene oxide per mole of cellulose instead of 0.48 in first step of the reaction.

HEMC for Ex 5

[43] Prepared as HEMC for Ex 3 except using a wood paste with an intrinsic viscosity of approximately 600 ml / g.

HEMC for Ex 6

[44] Prepared in the same way as HEMC for Ex 1 except the use of a cellulose paste with an intrinsic viscosity of approximately 1,300 ml / g and in the first reaction step uses 0.85 mol of ethylene oxide per mol of cellulose and, in the second stage of the reaction, it uses 1.6 moles of sodium hydroxide (50% by weight aqueous solution) per mole of cellulose.

HEMC for Ex 7

[45] Prepared in the same way as HEMC for Ex 1 except using a cellulose paste with an intrinsic viscosity of approximately 600 ml / g, in the first stage of the reaction uses 5.5 moles of dimethyl ether per mole of cellulose and 2.3 moles of methyl chloride per mole of cellulose, 2.2 moles of sodium hydroxide (50% by weight aqueous solution) per mole of cellulose, and 0.28 moles of ethylene oxide per mole of cellulose and , in the second stage of the reaction uses 2.3 moles of methyl chloride per mole of cellulose and 1.9 moles of sodium hydroxide per mole of cellulose (50% by weight aqueous solution).

HEMC for Comparative Example (Ex Comp) A

[46] Prepared in the same way as HEMC for Ex 1 except using a cellulose paste with an intrinsic viscosity of approximately 1,300 ml / g, in the first stage of the reaction uses 4.5 moles of dimethyl ether per mole of cellulose and 1.8 moles of sodium hydroxide (50% by weight aqueous solution) per mole of cellulose, and 0.14 moles of ethylene oxide per mole of cellulose and, in the second stage of the reaction, uses 0.8 moles of chloride methyl per mol of cellulose and zero mol of sodium hydroxide per mol of cellulose (50% by weight aqueous solution).

HEMC for Ex Comp B

[47] Prepared in the same way as HEMC for Ex 1 except the use of a cellulose paste with an intrinsic viscosity of approximately 1,300 ml / g, in the first stage of the reaction uses 0.14 mol of ethylene oxide per mol of cellulose and, in the second stage of the reaction, uses 0.2 mol of sodium hydroxide per mol of cellulose (50% by weight aqueous solution).

HEMC for Ex Comp C

[48] Prepared in the same way as HEMC for Ex 1 except using a cellulose paste with an intrinsic viscosity of approximately 1,300 ml / g, in the first stage of the reaction uses 0.75 mol of ethylene oxide per mol of cellulose and, in the second stage of the reaction uses 0.3 mol of sodium hydroxide per mol of cellulose (50% by weight aqueous solution).

HEMC for the Ex Comp D

[49] Prepared in the same way as HEMC for Ex 1 except the use of a cellulose paste with an intrinsic viscosity of approximately 1,300 ml / g.

HEMC for the Ex Comp E

[50] Prepared in the same way as HEMC for Ex 3 except using a cellulose pulp with an intrinsic viscosity of approximately 1,500 ml / g, in the first stage of the reaction uses 5.6 moles of dimethyl ether per mole of cellulose, 3.1 moles of methyl chloride per mole of cellulose, 2.4 moles of sodium hydroxide (50% by weight aqueous solution) per mole of cellulose, 0.35 moles of ethylene oxide per mole of cellulose, and the second stage of the reaction uses 1.5 moles of methyl chloride per mole of cellulose and 0.8 moles of sodium hydroxide (50% by weight aqueous solution) per mole of cellulose.

HEMC for the Ex Comp F

[51] Prepared in the same way as HEMC for Ex 1 except using a cellulose paste with an intrinsic viscosity of approximately 1,500 ml / g, in the first stage of the reaction uses 4.5 moles of dimethyl ether per mole of cellulose , 0.13 moles of ethylene oxide per mole of cellulose and in the second stage of the reaction uses 1.5 moles of sodium hydroxide (50% by weight aqueous solution) per mole of cellulose.

HEMC for the Ex Comp G

[52] Prepared in the same manner as HEMC for Ex 1 except the use of a cellulose paste with an intrinsic viscosity of approximately 1,800 ml / g.

HEMC for the Ex Comp H

[53] Prepared in the same way as HEMC for Ex 3 except the use of a cellulose paste with an intrinsic viscosity of approximately 1,500 ml / g.

HEMC for Ex Comp I

[54] Prepared in the same way as HEMC for Ex 1 except the use of a cellulose paste with an intrinsic viscosity having approximately 1,500 ml / g, in the first stage of the reaction uses 0.13 mol of ethylene oxide per mol of cellulose and in the second stage of the reaction uses 0.7 mol of sodium hydroxide (50% by weight aqueous solution) per mol of cellulose.

HEMC for the Ex Comp J

[55] Prepared in the same way as HEMC for Ex 1 except the use of a cellulose paste with an intrinsic viscosity of approximately 1,800 ml / g.

HEMC for the Ex Comp K

[56] Prepared in the same way as HEMC for Ex 1 except using a cellulose paste with an intrinsic viscosity of approximately 1,300 ml / g, in the first stage of the reaction uses 3.5 moles of dimethyl ether per mole of cellulose , 2.5 moles of sodium hydroxide (50% by weight aqueous solution) per mole of cellulose, and 1.7 moles of ethylene oxide per mole of cellulose and, in the second stage of the reaction, uses 2.8 moles of chloride methyl per mole of cellulose and 3.0 moles of sodium hydroxide (50% by weight aqueous solution) per mole of cellulose.

HEMC for the Ex Comp L

[57] Prepared in the same way as HEMC for Ex 1 except using a cellulose paste with an intrinsic viscosity of approximately 1,300 ml / g, in the first stage of the reaction uses 1.1 moles of ethylene oxide per mole of cellulose and in the second stage of the reaction uses 0.4 mol of sodium hydroxide (50% by weight aqueous solution) per mol of cellulose.

Characterization of the Example

[58] Table 2 provides characterizations of mortars of the present invention with different values of MS, DS and viscosity. It determines settlement, V-funnel time and leakage value and as previously described here. Determines the density of a fresh mortar immediately after preparation according to the method of DIN EN 12350-7.

[59] For each of these Examples, each of the settlement, funnel time V, pour value and density falls within the desired values for SCC mortar. As stated earlier, the desired values for an SCC mortar are a settlement greater than 290 millimeters, a V time less than five seconds and a leakage value less than that is three percent. For this particular mortar composition, it is desirable to have sufficiently low air entrapment in order to achieve a fresh density that is greater than 2000 kilograms per cubic meter. Each of the Examples that has a DS between 1.65 and 2.2 and an MS between 0.01 and 0.5 reaches 0.5 that the low level of air retention, in addition to the desired settlement, V-funnel time and leakage values. Table 2

[60] Table 3 provides characteristics for mortars that fall outside the scope of the present invention because HEMCs have a value for MS + DS that is below the range suitable for use in the present invention. The data in Table 3 reveals that the laying and, occasionally, the V funnel time of the resulting mortars are outside the desired range for SCC mortar (shown in bold and italics). Even though Exs Comps A to C have a desirable fresh density, they are unable to have desirable Settlement and V Funnel times, so they are outside the scope of the invention. Table 3

[61] Table 4 provides characteristics for mortars that fall outside the scope of the present invention because HEMCs have a viscosity of a 2% by weight aqueous solution that is greater than 30,000 mPa * s. The data in Table 3 reveal that when HEMC has a high viscosity (even if the MS + DS value is within the range) the settlement value and typically the funnel V time for the resulting mortar are outside the desired ranges for a SCC mortar (shown in bold and italics). Table 4

[62] Table 5 provides characteristics for additional mortars that fall outside the scope of the present invention because the viscosity values for HEMC are outside the claimed range (shown in bold). The data in Table 5 illustrates that these mortars have Mortar V Funnel times and typically settlement values that are outside the desired ranges for an SSC mortar (shown in bold and italics). Table 5

Claims (3)

1. Mortar comprising cement, one or more of a mineral additive, superplasticizer, aggregates, a hydroxyethyl methyl cellulose (HEMC) and water, in which the hydroxyethyl methyl cellulose is characterized by the fact that the sum of its molecular substitution (MS) of hydroxyethyl and degree of substitution (DS) of methyl is 1.90 to 2.30 and its viscosity in a 2 weight percent aqueous solution being below 30,000 milliPascal * second, at 20 ° C at a fixed shear rate of 2.55 sec-1 on a Rotovisco rheometer, in which MS and DS are determined by the Zeisel method of treating HEMC with hydrogen iodide and red phosphorus, and in which hydroxyethyl methyl cellulose (HEMC) has a molecular substitution (MS) of hydroxyethyl that is greater than 0.01 and less than or equal to 0.5 and a degree of substitution (DS) of methyl that is greater than 1.65 and less than 2.2. 2. Mortar according to claim 1, characterized by the fact that hydroxyethyl methyl cellulose is present at a concentration of 0.01 weight percent or more and 1.0 weight percent or less based on the total weight of cement. Mortar according to claim 1 or 2, characterized by the fact that it still comprises coarse and fine aggregate in order to form a concrete, in which the coarse aggregate has a greater total size distribution than the fine aggregate that passes through through a 9.5 mm sieve and up to 10 percent by weight through a 150 micrometer sieve, according to ASTM C33.